LIQUID-PHASE VOLUMETRIC AND MASS-TRANSFER COEFFICIENT, AND BOUNDARY OF HYDRODYNAMIC FLOW REGION IN PACKED COLUMN WITH COCURRENT DOWNWARD FLOW

Abstract: Gas purification from the content of H2S using Fe-EDTA (Iron Chelated Solution) gave several advantages. The advantages were the absorbent solution can be regenerated that means a cheap operation cost, the separated sulfur was a solid that is easy to handle and is save to be disposal to environment. This research was done by simulation and experimental. The simulation step was done by mathematical model arrangement representing the absorption process in packed column through mass transfer arrangement such as mass transfer equations and chemical reaction. The experimental step was done with the making of Fe-EDTA solution from FeCl2 and EDTA. Then Fe-EDTA solution was flown in counter current packed column that was contacted with H2S in the methane gas. By comparing gas composition result of experiment and simulation, the value of mass transfer coefficient in gas phase ( kAga), mass transfer coefficient in liquid phase (kAla) and the reaction rate constant ( k) were found. The values of mass transfer coefficient in liquid phase (kAla) were lower than values of mass transfer coefficient in gas phase (kAga) and the reaction rate constant (k). It meant that H2S absorption process using Fe-EDTA absorbent solution was determined by mass transfer process in liquid phase. The higher flow rate of absorbent, the higher value of mass transfer coefficient in liquid phase. The smaller packing diameter, the higher value of mass transfer coefficient in liquid phase.From analysis of dimension, the relation of dimensionless number between Sherwood number and flow rate of absorbent, packing diameter was Keywords: chemical reaction, Fe-EDTA, H2S absorption, mass transfer

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Gas holdup and volumetric liquid-phase mass transfer coefficient in bubble column with draught tube and with gas dispersion into annulus.

JOURNAL OF CHEMICAL ENGINEERING OF JAPAN ◽

10.1252/jcej.16.407 ◽

1983 ◽

Vol 16 (5) ◽

pp. 407-413 ◽

Cited By ~ 60

Author(s):

KOZO KOIDE ◽

HIROYUKI SATO ◽

SHINJI IWAMOTO

Keyword(s):

Mass Transfer ◽

Liquid Phase ◽

Transfer Coefficient ◽

Mass Transfer Coefficient ◽

Bubble Column ◽

Gas Holdup ◽

Liquid Phase Mass Transfer ◽

Gas Dispersion ◽

Draught Tube

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Mass Transfer Enhancement for CO2 Absorption in Structured Packed Absorption Column

Journal of the chemical society of pakistan ◽

10.52568/000803/jcsp/41.05.2019 ◽

2019 ◽

Vol 41 (5) ◽

pp. 820-820

Author(s):

Pongayi Ponnusamy Selvi and Rajoo Baskar Pongayi Ponnusamy Selvi and Rajoo Baskar

Keyword(s):

Mass Transfer ◽

Transfer Coefficient ◽

Mass Transfer Coefficient ◽

Gas Flow ◽

Aqueous Ammonia ◽

Volume Flow Rate ◽

Packed Column ◽

Operating Conditions ◽

Co2 Absorption ◽

Absorption Column

The acidic gas, Carbon dioxide (CO2) absorption in aqueous ammonia solvent was carried as an example for industrial gaseous treatment. The packed column was provided with a novel structured BX-DX packing material. The overall mass transfer coefficient was calculated from the absorption efficiency of the various runs. Due to the high solubility of CO2, mass transfer was shown to be mainly controlled by gas side transfer rates. The effects of different operating parameters on KGav including CO2 partial pressure, total gas flow rates, volume flow rate of aqueous ammonia solution, aqueous ammonia concentration, and reaction temperature were investigated. For a particular system and operating conditions structured packing provides higher mass transfer coefficient than that of commercial random packing.

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